An image detector has an I/V converter for converting, into a voltage output., a current output as a result of a photoelectric element arranged in a traveling direction of an intermediate transfer belt having received light reflected from the intermediate transfer belt and light reflected from toner images formed on the intermediate transfer belt; a peak-hold unit for holding an output voltage into which the light reflected from the intermediate transfer belt has been converted by the I/V converter; and a computation unit for detecting a difference between the output voltage of the peak-hold unit and an output voltage into which the light reflected from the toner images of respective colors has been converted by the I/V converter.
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8. An electrophotographic apparatus comprising:
a plurality of image forming units which electrify a photosensitive member that forms electrostatic images to thus form toner images on said photosensitive member;
an intermediate transfer belt on which said toner images of different colors formed on said photosensitive member are sequentially transferred in an overlapping manner by said respective image forming units; and
a registration correction control unit that aligns positions of said color toner images, wherein said registration correction control unit comprises:
an I/V converter that converts, into a voltage output, a current output as a result of a photoelectric element arranged in a traveling direction of said intermediate transfer belt receiving light reflected from said intermediate transfer belt and light reflected from said toner images formed on said intermediate transfer belt;
a peak-hold unit that holds an output voltage into which said light reflected from said intermediate transfer belt has been converted by said I/V converter; and
a computation unit that detects a difference between said output voltage of said peak-hold unit and an output voltage into which said light reflected from said toner images of respective colors is converted by said I/V converter.
14. An electrophotographic apparatus comprising:
a plurality of image forming units which electrify a photosensitive member, form electrostatic images on the photosensitive member, and develop the electrostatic latent images to form toner images;
an intermediate transfer belt on which said toner images of different colors formed on said photosensitive member are sequentially transferred in an overlapping manner by said respective image forming units; and
a registration correction control unit that aligns positions of said color toner images, wherein said registration correction control unit comprises:
two photoelectric elements;
two I/V converters that convert, into a voltage output, a current output with respect to each of said photoelectric elements arranged in a traveling direction of said intermediate transfer belt receiving light reflected from said intermediate transfer belt and light reflected from said toner images formed on said intermediate transfer belt;
two peak-hold units that hold output voltages into which said light reflected from said intermediate transfer belt has been converted by each of said two I/V converters; and
two computation units that detect differences between each of said output voltages of said two peak-hold units and both output voltages into which said light reflected from said toner images of respective colors is converted by each of said two I/V converters.
1. An electrophotographic apparatus comprising:
a plurality of image forming units which:
electrify a photosensitive member,
form electrostatic images, each being made up of an electrification potential portion and a discharge potential portion, on said photosensitive member by an exposure unit, and
develop said electrostatic latent images with toner, to thus form toner images on said photosensitive member;
an intermediate transfer belt on which said toner images of different colors formed on said photosensitive member are sequentially transferred in an overlapping manner by said respective image forming units; and
an image detector for detecting registration patches formed on said intermediate transfer belt with said color toner images, registration correction control for aligning positions of said color toner images being employed, wherein said image detector comprises:
an I/V converter for converting, into a voltage output, a current output as a result of a photoelectric element arranged in a traveling direction of said intermediate transfer belt receiving light reflected from said intermediate transfer belt and light reflected from said toner images formed on said intermediate transfer belt;
a peak-hold unit for holding an output voltage into which said light reflected from said intermediate transfer belt has been converted by said I/V converter; and
a computation unit for detecting a difference between said output voltage of the said peak-hold unit and an output voltage into which said light reflected from said toner images of respective colors is converted by said IV converter.
2. The electrophotographic apparatus according to
a clamper for preventing an output voltage of said photoelectric element which first receives said light reflected from said toner images from falling to or below a predetermined voltage; and
a comparator for comparing a clamp section output voltage with an output voltage of said computation section of said other photoelectric element, to thus output a timing signal showing the positions of said toner images.
3. The electrophotographic apparatus according to
4. The electrophotographic apparatus according to
a comparator that outputs a timing signal by comparing a reference voltage with said difference between said output voltage of the said peak-hold unit and an output voltage into which said light reflected from said toner images of respective colors is converted by said I/V converter.
5. The electrophotographic apparatus according to
6. The electrophotographic apparatus according to
7. The electrophotographic apparatus according to
9. The electrophotographic apparatus according to
a clamper prevents an output voltage of said photoelectric element which first receives said light reflected from said toner images from falling to or below a predetermined voltage; and
a comparator that compares a clamp section output voltage with an output voltage of said computation section of said other photoelectric element, to thus output a timing signal showing the positions of said toner images.
10. The electrophotographic apparatus according to
11. The electrophotographic apparatus according to
a comparator that outputs a timing signal by comparing a reference voltage with said difference between said output voltage of the said peak-hold unit and an output voltage into which said light reflected from said toner images of respective colors is converted by said I/V converter.
12. The electrophotographic apparatus according to
13. The electrophotographic apparatus according to
15. The electrophotographic apparatus according to
a clamper that prevents either output voltage of said two photoelectric elements which first receives said light reflected from said toner images from falling to or below a predetermined voltage; and
a comparator that compares a clamp section output voltage with an output voltage of said computation section of said other photoelectric element, to thus output a timing signal showing the positions of said toner images.
16. The electrophotographic apparatus according to
17. The electrophotographic apparatus according to
a comparator that outputs a timing signal by comparing,
a first difference from a first of said two computation units between a first output voltage of a first of said two peak-hold units and an output voltage into which said light reflected from said toner images of respective colors is converted by a first of said two I/V converters, with
a second difference from a second of said two computation units between said a second output voltage of said peak-hold units and an output voltage into which said light reflected from said toner images of respective colors is converted by a second of said two I/V converters.
18. The electrophotographic apparatus according to
a first difference between:
a voltage output from a first of said two I/V converters; and
an output voltage from a first of said two peak-hold units; and
a second difference between:
a voltage output from a second of said two I/V converters; and
an output voltage from a second of said two peak-hold units; are used to detect a position of a toner image.
19. The electrophotographic apparatus according to
20. The electrophotographic apparatus according to
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1. Field of the Invention
The present invention relates to a multicolor electrophotographic apparatus using an intermediate transfer belt.
2. Description of the Related Art
In association with a recent trend toward colorization and expedition of documents, faster color laser beam printers have been pursued rapidly.
A tandem color electrophotographic apparatus is mentioned as an example of a color printer. In this printer, toner of black (K), yellow (Y), magenta (M), and cyan (C) colors is used, and image forming means of respective colors are provided. Toner images formed on the respective image forming means are transferred to an intermediate transfer belt in a superimposing manner, to thus form a color image.
As shown in
Among reasons for the registration offset, an initial reason is manufacturing tolerances of the respective image forming means and mount tolerances of the same; and a time-varying reason is thermal expansion or deformation of members attributable to changes in the internal temperature of the electrophotographic apparatus. When laser is used as exposure means to be provided within the image forming means, the phase of a polygon mirror varies from one image forming means to another, which is in turn responsible for a registration offset.
For instance, as shown in
A technique using photoelectric elements as position detection means has been proposed. This technique uses two photoelectric elements for detecting the position of a light beam; specifically, as shown in
However, under circumstances where positions are detected by means of the light reflected from the intermediate transfer belt and the light reflected from the registration patches formed thereon, when the photoelectric elements 401, 402 are arranged as shown in
There has also been put forward a technique for detecting the amount of offset by means of a CCD sensor employed as another means for detecting the amount of offset. This technique is to take toner images having different reflection characteristics as base materials at the time of formation of registration patches and to detect black patches which have no reflection areas and are formed on the base materials. However, patches of different colors are formed as base materials for detecting the black patches, which raises another problem of an increase in the quantity of toner consumption (see Japanese Patent No. 2,761,287).
The above-described related-art techniques lack allowance for fluctuations in the intermediate transfer belt, the reflectivities of the respective color patches, and the quantity of toner consumption and suffer a problem of a decrease in the accuracy of detection of patch positions, which is caused by faulty detection stemming from fluctuations in the intermediate transfer belt or faulty operation due to noise.
An object of the present invention is to provide an electrophotographic apparatus which improves the accuracy of detection of the amount of positional offsets in registration patches performed by detection means and which can provide an image free from color offsets.
The objective is achieved by means of an electrophotographic apparatus comprising: a plurality of image forming means which electrify a photosensitive member; which form electrostatic images, each being made up of an electrification potential portion and a discharge potential portion, on the photosensitive member by means of exposure means; and which develop the electrostatic latent images with toner, to thus form toner images on the photosensitive member; an intermediate transfer belt on which the toner images of different colors formed on the photosensitive member are sequentially transferred in an overlapping manner by means of the respective image forming means; and image detection means for detecting registration patches formed on the intermediate transfer belt with the color toner images, registration correction control for aligning positions of the color toner images being employed, wherein the image detection means comprises I/V conversion means for converting, into a voltage output, a current output as a result of a photoelectric element arranged in a traveling direction of the intermediate transfer belt having received light reflected from the intermediate transfer belt and light reflected from the toner images formed on the intermediate transfer belt; peak-hold means for holding an output voltage into which the light reflected from the intermediate transfer belt has been converted by the I/V conversion section; and computation means for detecting a difference between the output voltage of the peak-hold means and an output voltage into which the light reflected from the toner images of respective colors is converted by the I/V conversion section.
According to the present invention, the accuracy of detection of the amount of registration offset can be enhanced without being affected by fluctuations in an intermediate transfer belt and noise and without involvement of an increase in the amount of toner consumed for registration patches; printing free from color displacement becomes feasible, and hence high-quality color printing becomes possible.
Embodiments of the invention will be described hereinbelow by reference to
The laser printer of the embodiment is equipped with the image forming means 102 to 105 which employ toner of black (K), yellow (Y), magenta (M), and cyan (C) colors and are provided for the respective colors, and the image forming means are uniformly spaced from each other and arranged vertically. Disposed beside the image forming means 102 to 105 is the intermediate transfer belt 101 on which the color toner images formed on the photosensitive drums 117 by the image forming means 102 to 105 are transferred in a superimposing manner.
Image forming operation will now be described by reference to
Subsequently, the latent image formed on the photosensitive drum 117 is developed with toner by the developing machine 120, to thus form a toner image. Next, the toner image formed on the photosensitive drum 117 is transferred on the intermediate transfer belt 101 by the first transfer machine 106. Residual toner, which has not been transferred to the intermediate transfer belt 101 and still remains on the photosensitive drum 117, is recovered by the drum cleaner 121.
Likewise, the image forming means 103 to 105 equipped with different colors of toner also form toner images on the respective corresponding photosensitive drums 117, and the first transfer machines 107 to 109 transfer toner images of respective colors onto the intermediate transfer belt 101. The toner images of the respective colors superimposed on the intermediate transfer belt 101 are transferred onto the paper 115 by means of the second transfer machine 110.
Finally, residual toner, which has not been transferred to the paper 115 and still remains on the intermediate transfer belt 101, is recovered by the belt cleaner 111, to thereby complete a round of printing processes. At this time, a registration patch is detected as follows. Namely, the registration patch 201 is formed on the intermediate transfer belt 101, which is set to a transport speed by a belt drive motor control section 301 shown in
Detection of a registration patch using photoelectric elements will be described hereinbelow.
At this time, when the light reflected from the intermediate transfer belt 101 has changed in association with a change in the intermediate transfer belt 101; for example, when the quantity of the light reflected from the intermediate transfer belt 101 has become larger, as shown in FIG. 6B2, a cross point between the voltage output from the photoelectric element 401 and the predetermined reference voltage Vref can be detected as the position of the patch, as shown in FIG. 6C2. When the quantity of the light reflected from the intermediate transfer belt 101 has become smaller, as shown in FIG. 6B3, the cross point between the output voltage of the photoelectric element 401 and the predetermined reference voltage Vref does not appear, as shown in FIG. 6C3, so that the position of the patch cannot be detected.
Below will be described detection of the registration patch which is not affected by the intermediate transfer belt and employs a difference between the light current output from the photoelectric element of the present embodiment for the intermediate transfer belt 101 and the light current output from the same for the patch 201.
As shown in
According to the foregoing embodiment, detection of the patch position employs the difference between the output V1P for the intermediate transfer belt 101 and the output V1 for the patch 201, and hence the center position of the patch 201 is not affected by variations in the intermediate transfer belt 101 and remains unchanged, whereby the position of the patch can be detected with high accuracy.
Detection of the related-art registration patch performed by the image detection means in which the two photoelectric elements are arranged in the transport direction of the intermediate transfer belt will be described hereinbelow by reference to
However, when the light reflected from the intermediate transfer belt 101 has changed in association with a change in the intermediate transfer belt 101; for example, when the quantity of the light reflected from the intermediate transfer belt 101 has become greater, as shown in FIG. 10B2, the light currents output from the photoelectric elements 401, 402 cross each other at a position where the voltage exceeds the clamp voltage set to a predetermined voltage by means of the quantity of light reflected from the patch 201, as shown in FIG. 10C2, and the output Vo representing the position of the patch is output at a position other than the original cross point. As a result, an error arises in the position of the patch, thereby resulting in a failure to perform highly accurate detection. When the quantity of the light reflected from the intermediate transfer belt 101 has become smaller, as shown in FIG. 10B3, the light current of the light reflected from the intermediate transfer belt 101 becomes equal to or smaller than the clamp voltage, as shown in FIG. 10C3. The cross point between the light currents output from the photoelectric elements 401, 402 and the light current originating from the intermediate transfer belt are perceived as the position of the patch, thus failing to perform highly accurate detection.
Detection of the registration patch, which is not affected by the intermediate transfer belt and which is performed by the image detection means formed by arranging two photoelectric elements of the present embodiment in the transport direction of the intermediate transfer belt, will be described hereinbelow by reference to
As shown in
Although a lower limit of the output V31 is limited by means of clamping, the portion of the output V31 that is higher than the clamp voltage becomes equal in waveform to the voltage output from the photoelectric element 40 in accordance with the quantity of incident light and is not affected by the clamp circuit 1101. For this reason, even when variations have arisen in the quantity of light entering the photoelectric elements 401, 402, the position where the cross point is detected remains unchanged, thereby enabling highly accurate detection. Moreover, no cross point appears for the outputs V3, V4 produced as a result of detection of the intermediate transfer belts 101, and hence faulty operation does not arise.
There are adopted the difference between the output V1P produced for the light reflected from the intermediate transfer belt 101 and the light V1 reflected from the patch 201 and the difference between the outputs V2P and V2. Hence, even when variations have arisen in the intermediate transfer belt 101 and variations have also arisen in the quantity of light entering the intermediate transfer belt 101, no variations arise in the output voltages originating from the intermediate transfer belt 101, the voltages being output as the outputs V3, V4, and the outputs do not exceed the clamp voltage. Therefore, the position where the cross point is detected does not change, and the position of the patch can be detected with high accuracy.
In the foregoing embodiment, the difference between the output VP1 for the intermediate transfer belt 101 and the output V1 of the patch 201 and the difference between the output V2P for the intermediate transfer belt 101 and the output V2 for the patch 201 are also used for detecting the position of the patch. Hence, the position where the cross point is to be detected is not affected by variations in the intermediate transfer belt and does not change, and hence the position of the patch can be detected with high accuracy.
A method of the detection means will now be described by reference to
The patch detection method of the embodiment will be described hereinbelow. As shown in
As shown in
According to the foregoing embodiment, the light reflected from the intermediate transfer belt and that reflected from the patch are detected in the form of regular reflected light. As a result, the intermediate transfer belt and the K patch can be distinguished from each other, and there is yielded an effect of the ability to detect the amount of registration offset without involvement of an increase in the quantity of toner consumption.
A method for setting the clamp voltage will be described by reference to
According to the previously-described embodiment, as a result of the clamp voltage being set so as to become equal to or higher than the expected noise or equal to or lower than the cross point achieved at the time of detection of the patch, the position where the cross point is to be detected remains unchanged, so that the position of the patch can be detected with high accuracy without being affected by the quantity of light entering the sensor.
Akatsu, Shinichi, Sakamoto, Junshin
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Jul 13 2004 | AKATSU, SHINICHI | HITACHI PRINTING SOLUTIONS, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 015689 | /0012 | |
Jul 13 2004 | SAKAMOTO, JUNSHIN | HITACHI PRINTING SOLUTIONS, LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 015689 | /0012 | |
Aug 13 2004 | Ricoh Printing Systems, Ltd. | (assignment on the face of the patent) | / | |||
Oct 01 2004 | HITACHI PRINTING SOLUTIONS, LTD | Ricoh Printing Systems, LTD | CHANGE OF NAME SEE DOCUMENT FOR DETAILS | 016230 | /0122 |
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